Capacitive Touch Sensor Apparatus Having Electromechanical Resonators

1. A capacitive touch sensor system comprising: a substrate layer; and a plurality of resonant circuits, each comprising: a respective electrode, the electrodes of the plurality of resonant circuits being distributed on the substrate layer; a respective electromechanical resonator connected to the respective electrode, wherein each electromechanical resonator has a Quality (Q) factor of at least 200; and a respective pulling capacitor connected between the respective electrode and a device ground and in parallel with the electromechanical resonator, the pulling capacitor having a capacitance that shifts resonance of the resonant circuit away from a peak resonance frequency of the electromechanical resonator; and a signal generator that generates drive signals at about the peak resonance frequencies of the electromechanical resonators of the plurality of resonant circuits to drive the plurality of resonant circuits.

2. The capacitive touch sensor system of claim 1 , wherein the electromechanical resonators comprise one or more ceramic resonators.

3. The capacitive touch sensor system of claim 1 , wherein the electromechanical resonators comprise one or more crystal resonators.

4. The capacitive touch sensor system of claim 1 , wherein the electromechanical resonators comprise one or more MEMs resonators.

5. The capacitive touch sensor system of claim 1 , wherein each electromechanical resonator has a Q factor of at least 800.

6. The capacitive touch sensor system of claim 1 , wherein the electromechanical resonators are tunable, such that the resonant circuits comprise tunable resonant filters.

7. The capacitive touch sensor system of claim 1 , wherein each electromechanical resonator is connected between the respective electrode and a drive input.

8. The capacitive touch sensor system of claim 7 , wherein each resonant circuit further comprises a resistor connected between the respective electrode and the drive input.

9. The capacitive touch sensor system of claim 1 , wherein each resonant circuit further comprises a static discharge resistor connected in parallel with the capacitor between the respective electrode and ground.

10. The capacitive touch sensor system of claim 1 , wherein the plurality of resonant circuits have a plurality of resonance frequencies.

11. The capacitive touch sensor system of claim 10 , wherein the plurality of resonance frequencies are spaced apart from each other by a frequency separation of at least 40 kHz.

12. A system comprising: a capacitive touch sensor of comprising: a substrate layer; and a plurality of resonant circuits, each resonant circuit comprising: a respective electrode, the electrodes of the plurality of resonant circuits being distributed on the substrate layer; and a respective electromechanical resonator connected to the respective electrode, wherein each electromechanical resonator has a Quality (Q) factor of at least 200; and a respective pulling capacitor connected between the respective electrode and a device ground and in parallel with the electromechanical resonator, the pulling capacitor having a capacitance that shifts resonance of the resonant circuit away from a peak resonance frequency of the electromechanical resonator; and a controller operatively connected to the capacitive touch sensor apparatus, the controller comprising: a processor; a signal generator, operably connected to the processor, that generates, as output, drive signals at about the peak resonance frequencies of the electromechanical resonators of the plurality of resonant circuits to drive the capacitive touch sensor apparatus; a broadband filter that receives, as input, signals output from the capacitive touch sensor apparatus; and a detector that receives the signals from the capacitive touch sensor apparatus, thus filtered by the broadband filter.

13. The system of claim 12 , wherein the broadband filter has a passband that encompasses all of the plurality of resonance frequencies.

14. The system of claim 12 , the controller further comprising a pre-amplifier that amplifies the signals output from the capacitive touch sensor apparatus prior to the signals being input to the broadband filter.

15. The system of claim 12 , the controller further comprising a switch, a first output terminal and a second output terminal, wherein the switch is controllable by the processor to selectively direct the drive signals to the first output terminal and the second output terminal.

16. A method for a capacitive touch sensor comprising a plurality of resonant circuits having a plurality of resonance frequencies, each of the resonant circuits comprising an electromechanical resonator having a Quality (Q) factor of at least 200, the method comprising: exciting the plurality of resonant circuits with signals at about peak resonances of the electromechanical resonators of the plurality of resonance frequencies, each of the resonant circuits further comprising a respective pulling capacitor connected between a respective electrode and a device ground and in parallel with the electromechanical resonator, the pulling capacitor having a capacitance that shifts resonance of the resonant circuit away from a peak resonance frequency of the electromechanical resonator; receiving response signals from the plurality of resonant circuits; and detecting one or more touch events by measuring the response signals.

17. The method of claim 16 , further comprising filtering the response signals with a broadband filter, wherein the broadband filter has a passband that encompasses the plurality of resonance frequencies.

18. The method of claim 17 , further comprising, prior to said filtering, amplifying the response signals.

19. The method of claim 17 , further comprising, after said filtering, amplifying the filtered response signals.

20. The method of claim 16 , wherein the electromechanical resonators comprise at least one of: ceramic resonators; crystal resonators; and MEMs resonators.